The Formation of the ω Phase in the Titanium-iron System under Shear Deformation

In this work, the effect of the phase composition on the alpha/beta-Ti(Fe) -> omega-Ti(Fe) transformation under shear strain with high pressure torsion (HPT) was studied in the Ti-4wt.%Fe alloy. For shear deformation by means of HPT, two initial states of the alloy were used, which significantly differed in the morphology of the phases and the concentration of iron atoms in the beta phase. During HPT, a stationary state occurred in both sample series, which is characterized by the presence of a single omega phase containing 4wt.%Fe and by a grain size of about 200 nm. Thus, the HPT state is equifinal and independent of the initial phase composition of the samples. It was found that under the influence of HPT in Ti-4wt.%Fe alloys not only martensitic (shear) transformation into the omega phase occurs, but also a significant mass transfer of atoms of the alloying element. An analysis of the change in torsion directly in the HPT process made it possible to estimate the rate of deformation-induced mass transfer. It is 18-19 orders of magnitude higher than the rate of conventional thermal diffusion at the processing temperature T-HPT = 30 degrees C, while it is close to the diffusivity values at 700-800 degrees C. This is due to the fact that HPT increases the concentration of lattice defects, which in turn is equivalent to an increase in temperature. A similar combination of accelerated mass transfer during HPT and martensitic (shear) transformation was previously observed in copper-based shape memory alloys, but for the first time studied for the formation of omega-phase in titanium alloys.